Micro-fluidic chambers for use in liquid medicament delivery systems

ABSTRACT

Micro-fluidic chambers for use in a liquid medicament delivery system, include a bottom substrate and a top cover, the top cover being spaced from the bottom substrate so as to define a height of the chamber, wherein, one or more walls or fillings are positioned in the chamber, the walls or fillings defining a fluid channel there between such that the fluid channel extends from an inlet conduit to an inlet of the chamber to an outlet conduit connected to an outlet of the chamber, wherein, each of the walls or fillings has a height less than the height of the chamber so as to define a fluid gap between a top surface of each wall or filling and the top cover; and wherein, the dimensions of the walls or fillings and the chamber are such that the fluid gap will be filled with liquid by capillary forces via the fluid channel when liquid is introduced into the fluid chamber

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No.012/877,569 filed on Sep. 28, 2010, which claims priority to EuropeanPatent application Ser. No. EP09170095.5 filed on Sep. 11, 2009, whichis incorporated by reference herein.

TECHNICAL FIELD

This specification relates to micro-fluidic chambers for use in liquidmedicament delivery systems, pressure sensors, degassing devices andinfusion pump devices.

BACKGROUND

Devices for the automated release of liquid medicaments can be used withpatients who have a continuous and/or, in the course of the day, avarying need of a medicine that can be administered by subcutaneousinfusion. Specific applications include, for example, certain paintherapies and the treatment of diabetes. In such cases, computercontrolled infusion pump devices may be used, which can be carried bythe patient on the body, and which contain a certain amount of liquidmedicament in a medicine reservoir. The medicine reservoir can compriseenough medicine sufficient for one or several days. Furthermore, theliquid medicament can be supplied to the patient's body from themedicine reservoir through an infusion cannula or an injection needle.

In self-administration of medicaments, such as, for example, insulin,the patients using the medicament in question and administering itthemselves by means of an infusion pump device may seek convenience anddiscretion. As a consequence, the acceptable dimensions of such infusionpump devices may be limited in order not be evident through clothing andto be carried in a comfortable manner. In one type of infusion pumpdevice, the liquid medicament may be obtained by a downstream pump froma flexible container. Flexible containers can comprise a smaller volumesurplus of the container in relation to its content, which can reducethe manufacture costs and the achievable overall dimensions of aninfusion pump device with such a flexible container.

However, infusion pump devices can include air bubbles in the fluidicsystem, particularly in the pump system, and in other components, suchas the container. If air bubbles remain in the fluidic system, they maybe administered instead of the liquid medicament. Also, due to the highcompressibility of gases in relation to liquids such as water, the aircan reduce the stiffness of the fluidic system, which may limit thepotential detection of blockages or occlusions in the fluidic systemwhen monitoring the fluidic pressure. Furthermore, fluidic systems caninclude dead volume which may not be emptied or drained completely.Thus, since a certain percentage of the liquid medicament inevitablyremains in the fluid system and has to be disposed, the dead volume canincrease the costs per dose and thus of the overall therapy costs.

Micro-fluidic chambers can be used, for example, as sensor chambers inpressure sensors for fluidic systems. Such pressure sensors can comprisea chamber filled with liquid that is fluidly connected to the fluidicsystem. The chamber can be covered by a flexible, resilient membrane,such that a pressure difference between the fluidic pressure inside thesensor chamber and the outside (atmospheric) pressure will temporarilydeform the membrane. The resulting deflection of the membrane can thenbe measured to determine the internal pressure of the fluidic system.

One possible approach to measure the deformation of the membraneincludes the optical detection of a light beam reflected by themembrane. Another possible approach can include capacitive sensing, inwhich the flexible, resilient membrane of the chamber acts as acapacitor electrode. When the membrane is deformed, the capacitancebetween the membrane capacitor electrode and a second capacitorelectrode changes and is measured to determine the pressure differenceacting on the membrane. Yet another possible approach to measure thedeformation of the membrane is the use of strain gauges mounted to themembrane. In the context of liquid medicament administration via aninfusion pump device, these exemplary pressure sensors, as well asalternative apparatuses and methods, may be used for controlling thedosing, monitoring the correct operation of the system, and detectingfaults and hazards, such as occluded infusion lines or cannulae, emptycontainers, or malfunctioning pump systems. However, air bubbles in thein the micro-fluidic sensor chamber can reduce the stiffness of thefluidic system, and thus delay the response of the sensor to pressurechanges in the fluidic system. The resulting irreproducible measurementerrors may reduce the dosing accuracy of an infusion pump device, andincrease the response time to an occlusion event.

Micro-fluidic chambers may also be employed as degassing devices forfluidic systems, particularly infusion pump devices, in which a liquidfilled chamber may be covered by a gas-permeable membrane. Subject tothe condition that there is a positive difference between the partialpressure of the gas present in the fluidic system and the pressure onthe opposite side of the permeable membrane, gas, as bubbles or solvedin the liquid, can leave the fluidic system by permeating through themembrane. In such uses, the properties of the micro-fluidic chamber andthe performance of devices using such chambers may be independent on theorientation of the micro-fluidic chamber with respect to the gravityfield, since the orientation of the device during application isundefined and may constantly change

Thus, to limit or avoid air bubbles in the micro-fluidic chamber whenthe fluidic system is filled the first time, the so called priming ofthe system, the chamber may be filled in a controlled manner. However,the micro-fluidic chamber may comprise an uncontrolled orientationduring this first filling procedure since the gravitation field leads tobuoyancy forces that act on the air bubbles. Depending on theorientation and the design of the micro-fluidic chamber, air bubbles maybe caught in certain areas of the chamber.

Accordingly, a need exists for alternative micro-fluidic chambers foruse in liquid medicament delivery systems.

For the present specification the meaning of the term “air” shall notonly include air as such, but any gas or composition of gases that maybe present in a fluidic system, particularly pure nitrogen or otherprotective gases.

SUMMARY

In one embodiment, a micro-fluidic chamber for use in a liquidmedicament delivery system, is provided. The micro-fluidic chamberincludes a bottom substrate and a top cover, the top cover being spacedfrom the bottom substrate so as to define a height of the micro-fluidicchamber. The one or more walls or fillings may be positioned in themicro-fluidic chamber such that the walls or fillings form a fluidchannel there between and such that the fluid channel extends from aninlet conduit connected to an inlet of the micro-fluidic chamber to anoutlet conduit connected to an outlet of the micro-fluidic chamber. Eachof the walls or fillings may have a height less than the height of themicro-fluidic chamber so as to define a fluid gap between a top surfaceof each wall or filling and the top cover, and the dimensions of thewalls or fillings and the chamber may be such that the fluid gap will befilled with liquid by capillary forces via the fluid channel when liquidis introduced into the micro-fluidic chamber. Further, the top covercomprises a flexible membrane.

In another embodiment, a method for delivering medicament to a patientis provided. The method comprises utilizing a liquid medicament deliverysystem having a micro-fluidic chamber. The micro-fluidic chamberincludes a bottom substrate and a top cover, the top cover being spacedfrom the bottom substrate so as to define a height of the micro-fluidicchamber. The one or more walls or fillings may be positioned in themicro-fluidic chamber such that the walls or fillings form a fluidchannel there between and such that the fluid channel extends from aninlet conduit connected to an inlet of the micro-fluidic chamber to anoutlet conduit connected to an outlet of the micro-fluidic chamber. Eachof the walls or fillings may have a height less than the height of themicro-fluidic chamber so as to define a fluid gap between a top surfaceof each wall or filling and the top cover, and the dimensions of thewalls or fillings and the chamber may be such that the fluid gap will befilled with liquid by capillary forces via the fluid channel when liquidis introduced into the micro-fluidic chamber.

In yet another embodiment a pressure sensor for use in a liquidmedicament delivery system is provided. The pressure sensor includes arigid bottom structure and a top cover, the top cover including aflexible, resilient membrane being spaced from the rigid bottomstructure so as to define a height of a chamber. The one or more wallsor fillings may be positioned in the chamber, the walls or fillingsdefining a fluid channel there between such that the fluid channelextends from an inlet conduit connected to an inlet of the chamber to anoutlet conduit connected to an outlet of the chamber. Each of the wallsor fillings may have a height less than the height of the chamber so asto define a fluid gap between a top surface of each wall or filling andthe top cover and the dimensions of the walls or fillings and thechamber are such that the fluid gap will be filled with liquid bycapillary forces via the fluid channel when liquid is introduced intothe chamber. Furthermore, when there is no pressure difference betweenan external pressure of the chamber and an internal pressure of thechamber, the top cover remains flat, and when the external pressure ofthe chamber is less than the internal pressure, the top cover bulgesoutwards.

These and additional features provided by the embodiments describedherein will be more fully understood in view of the following detaileddescription, in conjunction with the drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

The embodiments set forth in the drawings are illustrative and exemplaryin nature and not intended to limit the subject matter defined by theclaims. The following detailed description of the illustrativeembodiments can be understood when read in conjunction with thefollowing drawings where like structure is indicated with life referencenumerals and in which:

FIG. 1A schematically depicts a top view of a micro-fluidic chamberaccording to one or more embodiments shown and described herein;

FIG. 1B schematically depicts a cross-section along plane A-A of FIG. 1Aaccording to one or more embodiments shown and described herein;

FIG. 1C depicts an enlarged view of a portion of FIG. 1B according toone or more embodiments shown and described herein;

FIG. 2A the distribution of liquid in a real experiment during a firststage of the filling of the a micro-fluidic chamber according to one ormore embodiments shown and described herein;

FIG. 2B the distribution of liquid in a real experiment during a secondstage of the filling of the a micro-fluidic chamber according to one ormore embodiments shown and described herein;

FIG. 3A depicts a micro-fluidic chamber according to one or moreembodiments shown and described herein;

FIG. 3B depicts another micro-fluidic chamber according to one or moreembodiments shown and described herein;

FIG. 3C depicts yet another micro-fluidic chamber according to one ormore embodiments shown and described herein;

FIG. 3D depicts even yet another micro-fluidic chamber according to oneor more embodiments shown and described herein;

FIG. 4A depicts a top view of a micro-fluidic chamber with a straightfluid channel according to one or more embodiments shown and describedherein;

FIG. 4B depicts the cross-section along plane A-A of FIG. 4A accordingto one or more embodiments shown and described herein;

FIG. 5 depicts a micro-fluidic chamber with a single wall arranged inthe centre of the chamber according to one or more embodiments shown anddescribed herein;

FIG. 6A depicts an optical detection scheme for the measurement of thedisplacement of the top membrane of a micro-fluidic chamber of apressure sensor according to one or more embodiments shown and describedherein;

FIG. 6B depicts another optical detection scheme for the measurement ofthe displacement of the top membrane of a micro-fluidic chamber of apressure sensor according to one or more embodiments shown and describedherein;

FIG. 7A depicts a capacitance detection scheme for the measurement ofthe displacement of the top membrane of a micro-fluidic chamber of apressure sensor according to one or more embodiments shown and describedherein;

FIG. 7B depicts another capacitance detection scheme for the measurementof the displacement of the top membrane of a micro-fluidic chamber of apressure sensor according to one or more embodiments shown and describedherein;

FIG. 8 depicts an embodiment of a degassing device with a micro-fluidicchamber according to one or more embodiments shown and described herein;

FIG. 9A depicts a micro-fluidic chamber with additional outlets alongthe fluidic channel in the chamber, providing bubble-trap capabilities,according to one or more embodiments shown and described herein; and

FIG. 9B depicts a micro-fluidic chamber with a bypassing additionalconduit according to one or more embodiments shown and described herein.

DETAILED DESCRIPTION

Referring to FIGS. 1A-1C, an exemplary embodiment of a micro-fluidicchamber is illustrated. A circularly shaped fluid chamber 1 can comprisea bottom substrate 11 and a top cover 12. The top cover 12 may be spacedfrom the bottom substrate 11 by a certain height H1, thus defining aninner volume 14 of the chamber 1. In one embodiment, eight walls 13 maybe arranged in the fluid chamber 1 (as best illustrated in FIG. 1A, anddefine a meander-like (e.g., bending, weaving or curving) fluid channel2 that runs from an inlet 21 to an outlet 22 located on the oppositeside of the chamber 1. Thus the inlet conduit 211 and the outlet conduit221 can be fluidly connected by the fluid channel 2.

The height H2 of the walls 13 may be less than the overall height H1 ofthe chamber 1. As a result, there may be a fluid gap 3 between the topcover 12 and the upper surface 131 of the walls 13, with a heightH3=H1−H2. The dimensions of the chamber and the walls, particularly theheights H1, H2, H3 may be chosen such that there are non-negligiblecapillary forces acting on a fluid 4 present in the micro-fluidicchamber 1. Fluid 4 in the fluid channel 2 may be dragged by saidcapillary forces into the fluid gap 3.

In one embodiment, the specific dimensions may depend on the liquidused. In another embodiment, the specific dimensions may additionally oralternatively depend on the properties of the surfaces of the top cover12 and the top 131 of the walls 13., Such factors may eventually definethe interface tensions between the liquid, surfaces, and the gas/air inthe chamber, which then may define the effective capillary forces for acertain geometric setting of a micro-fluidic chamber. In one exemplaryembodiments, where liquid medicaments are aqueous solutions, at leastsome surfaces, such as the surface of the top surface 131 of the wall 13and the surface of the top cover 12 facing toward surface 131, may behydrophilic, with a contact angle<90°. Such an embodiment may therebyincrease the overall capillary effect. In another exemplary embodiment,where the liquid medicaments are aqueous solutions, the height H3 of thegap 3 may comprise between 20 and 200 μm. In another embodiment, theheight H3 of the gap 3 may comprise between 50 and 150 μm.

In one embodiment, a diameter of a micro-fluidic chamber 1 may, forexample, comprise between about 2 to 10 mm. In another embodiment, thefluid channels may comprise a width of, for example, 0.1 to 1 mm, whilethe height H2 of the walls 13 comprise between 0.25 to 5 mm, oralternatively, 0.5 and 1 mm. In yet another embodiment, the aspect ratiobetween the width of the fluid channel 2 and the height H2 can liebetween 0.25 and 5, or alternatively, comprise about 1.

When a micro-fluidic chamber 1 according is filled through inlet 21 witha liquid 4, the liquid may flow essentially along the fluid channel 2.The capillary forces may then drag liquid 4 in the fluid channel 2 intothe adjacent sections of the gap 3, thereby effectively supplanting airpresent in the gap. As it may be energetically more favorable for air toform spherical bubbles with minimum surface toward the hydrophilicsurroundings, no or minimal air bubbles may remain in the gap 3.

Referring now to FIGS. 2A-2B, the first filling of a micro-fluidicchamber 1 of a liquid medicament delivery system 100 is illustrated.Specifically, in FIG. 2A an aqueous liquid 4 has flown downstreamthrough inlet conduit 211 and inlet 21 into the fluid channel 2, and iscurrently at a position B. Due to the capillary forces in the gap 3, theliquid 4 flows into the sections 3.1, 3.2 3.3, 3.4 of gap 3 adjacent tothe fluid channel 2 already filled. In the gap, the surrounding stillempty sections of the fluid channel 2, downstream of position B, limitthe further flow of the liquid. Thus, the gap 3 filled section bysection. Referring no to FIG. 2B, at a later stage, the liquid 4 hasproceeded in the fluid channel 2 to a position C. All sections of thegap 3 are filled except section 3.10, which has not yet come intocontact with the liquid 4. As illustrated in FIGS. 2A-2B, no air remainsin the part of the chamber that has already been filled by liquid. Whenthe liquid finally reaches the outlet 22 and the outlet conduit 221, themicro-fluidic chamber may be completely filled with no or minimal airbubbles remaining in the chamber.

Air bubbles in the gap may be energetically less preferable than airbubbles in the fluid channel 2. As a consequence, air bubbles may notform in the gap 3 at a later stage, and if they do, they will migrateinto the fluid channel 2. Air bubbles in the fluid channel 2, on theother hand, may not enter the gap 3 for energy reasons, but may betransported away by the liquid stream.

The shown capabilities of a micro-fluidic chamber 1 may be independentfrom its orientation in space. Since the capillary forces and interfacetensions responsible for the smooth filling of the gap can be strongerthan the gravitational force acting on the liquid, as well as thebuoyancy force acting on the air bubbles in the liquid, themicro-fluidic chamber may be completely filled with liquid 4 independenton its orientation. Thus, the filling behavior of such a micro-fluidicchamber may become more predictable and reproducible.

Since the operational internal volume of a micro-fluidic chamber may besmaller than that of a hollow micro-fluidic chamber with similardimensions, the dead volume—the portion of the fluid volume in a fluidsystem that can never be drained and eventually will be lost—may beconsiderably reduced.

Furthermore, the air bubbles that do enter the chamber through the inletmay be guided through the fluid channel to the outlet. Since theeffective cross-sectional area of the fluid channel may be essentiallyconstant over its length, the liquid flow may also be constant over itslength, and does not drop at certain positions. Thus, bubbles may not becaught in the fluid chamber.

Still referring to FIGS. 1A-2B, a micro-fluidic chamber may have anyother suitable shape as well as the specific design of the fluid channelin the chamber, both of which may depend on the specific application ofthe micro-fluidic chamber. For example, referring now to FIGS. 3A-3D,possible variants of micro-fluidic chambers are illustrated.Specifically, in the embodiment illustrated in FIG. 3A, the meanders ofthe fluid channel 2 may be arranged in an elliptically shaped chamber 1,while in the embodiment illustrated in FIG. 3B, the chamber 1 maycomprise a substantially rectangular shape. In the embodimentillustrated in FIG. 3C, a circularly shaped chamber 1 can comprise analternative course of a meandering fluid channel 2.

Alternatively, instead of having a single fluid channel 2, the walls 13of a micro-fluidic chamber may define two or more fluid channels withinthe chamber, extending from a common inlet to a common outlet. Forexample, such an embodiment of an exemplary micro-fluidic chamber 1 isillustrated in FIG. 3D. In such an embodiment, an inlet conduit 211 mayopen towards the chamber 1 through a common inlet 21. The fluid channelmay then split up into two separate fluid channels 2, 2′, and may joinagain at a common outlet 22. In such an embodiment, constructive meanssuch as flow barriers may be provided to ensure that during the fillingprocedure the chamber 1 is completely filled before the liquid flowproceeds further through the outlet 22.

A curved or meandering design of the fluid channel may be utilized influid chambers with larger base areas, since the longest possibledistance between the fluid channel and an outer edge of the gap isrelatively short. In addition, the meandering fluid channel can be usedto limit the maximum flow through a fluidic system.

In yet another embodiment, a straight fluid channel may be utilized inmicro-fluidic chambers. For example, such an embodiment of amicro-fluidic chamber 1 comprising a straight fluid channel isillustrated in FIG. 4A-4B. In such an embodiment, a straight fluidchannel 2, arranged in a circularly shaped chamber 1, may be in linewith the inlet conduit 211 and the outlet conduit 221. Liquid 4 passingthrough the fluid channel 2 may be dragged into the two adjacentsections 3.1, 3.2 of the gap 3 on both sides of the fluid channel 2.Such an embodiment of a micro-fluidic chamber 1 may reduce the overallinner volume of the chamber 1 in relation to the area of the gap 3 andmay also reduce flow resistance compared to a meander-shaped fluidchannel.

Referring now to FIG. 5, yet another embodiment of a micro-fluidicdevice 1 is illustrated, wherein two fluid channels 2, 2′ run from acommon inlet 21 along the edge of the chamber 1 to a common outlet 22. Asingle wall or filling 13 may be arranged in the centre of the chamber1. The resulting central gap 3 may thus be defined by the volume betweenthe large circular top surface of the wall 13 and the top cover. Similarto the embodiment illustrated in FIG. 3D, constructive barriers such asa flow barriers may be used to ensure a complete filling of the chamber.

Referring now to FIGS. 1A-5, as discussed above, the fluid chamber 1comprises a bottom structure 11 and a top cover 12, which may be sealedtogether in a sealing area 15 along an outer rim of the chamber 1. Thebottom substrate 11 and the top cover 12 may comprise any suitablematerial or materials such as, for example, polymeric materials.Furthermore, any suitable method may be used to connect the twosubstrates 11, 12 such as, for example, thermal bonding, laser bonding,gluing etc.

In one embodiment, the walls 13 may be realized as an integral part ofthe bottom substrate 11. In such an embodiment, the fluid channel 2, andeven the inlet and outlet conduits can, as an example, be produced byembossing the necessary void structures into a flat bottom structure 11.To obtain the necessary gap 3, one may arrange a thin spacer layer withheight H3 between the bottom layer structure and the top layer 12 aroundthe chamber, or may produce the gap together with the fluid channel andthe walls in the embossing step. In an alternative embodiment, themicro-fluidic chambers may be manufactured via injection molding.

In one particular embodiment, the walls 13 may comprise separate fillingstructures, mounted onto a flat bottom layer 11. In such an embodiment,a filling body may be attached to a bottom layer, and then may bearranged between said bottom layer and a adjacent top layer in asandwich-like manner.

Such micro-fluidic chambers may thereby be manufactured in large numbersand on continuous production lines which may, for example, reduce theeffective costs per piece and increase their viable use as with fordisposable products, such as for parts of an infusion pump device thatare disposed after use for hygienic reasons.

In one embodiment, the micro-fluidic chamber may be used with pressuresensors for fluidic systems, such as, for example, for pressure sensorsfor miniaturized pump systems such as infusion pump devices for liquidmedicaments. For example, a pressure sensor with a micro-fluidic chambermay comprise a rigid bottom structure 11 and a flexible, resilientmembrane 120 as the top layer 12. When there is no pressure differencebetween the external pressure and the internal pressure of the fluidicsystem, the top layer membrane 120 may remain flat. In the case of apositive pressure difference, the membrane 120 may bulge outwards. Theresulting displacement of the outer surface of the flexible membrane 120then may be used to determine the current pressure difference. In thecase of a negative pressure difference, where the flexible membrane 120may be displaced inwards toward the chamber 1, the walls 13 may supportthe membrane 120, thereby avoiding an occlusion of the micro-fluidicchamber 1, or even damage of the membrane 120. In such embodiments, thepressure sensor with a micro-fluidic chamber may comprise reduced deadvolume.

In an alternative embodiment of a micro-fluidic chamber for use in apressure sensor, the roles of the bottom substrate and the top layer maybe reversed. In such a variant, the top layer may comprise a rigidstructure, while the bottom substrate may comprise a flexible, resilientmembrane. Thus, the walls or fillings may protrude from the flexiblemembrane. To measure the pressure in the fluid system, the deformationof the flexible bottom structure may be measured.

In such embodiments, various systems may be utilized to measure thedisplacement of the flexible membrane 120. For example, referring toFIGS. 6A-6B, two possible embodiments of detection systems 5 based onoptical principles are illustrated. Specifically, FIG. 6A illustrates across-section of a micro-fluidic chamber 1 similar to that illustratedin FIGS. 1A-1C. The top cover 12 may be realized as a flexible,resilient membrane layer 120, sealed 15 to the basic structure 11 alongthe outer rim of the chamber 1. An optical detection system 5 maycomprise a light emitting device 51, such as, for example, a lightemitting diode (LED) or a laser diode, and a photo sensor 52, such as,for example, a photo diode or a photo transistor. The light emittingdevice 51 and the photo sensor 52 may be arranged such that an incidentlight beam 53 emitted by the light emitting device 51 is reflected 54 bythe surface of the top cover 12 toward the photo sensor 52, where it maybe detected. In one embodiment, the top cover may be metal vapor coatedto increase reflection. When the top cover 12 bulges under a positivepressure difference (as illustrated as dashed lines 120′), the reflectedlight beam 54′ does not impinge any longer on photo sensor 52. In suchan embodiment, the detection system 5 may thereby deliver a binaryon/off signal correlated to a certain pressure threshold, which may beused by a control unit of an infusion pump system. Such a system maythereby detect occlusion in a fluid line. In another embodiment, toachieve a higher resolution in the pressure values, a sensor array maybe used instead of a single sensor. Such an embodiment may be utilizedwhere the pressure values are used by a control unit to calculate thecurrent flow of liquid and the administered dose of liquid medicament.

Referring now to FIG. 6B, another embodiment of an optical detectionsystem is illustrated wherein the light emitting device 51 and the photosensor 52 are arranged in such a way that the reflected light beam 54will fall onto the photo sensor 52 independent of a displacement of thetop cover membrane 120, 120′. The position of the surface of the topcover 12 may be determined by analyzing the amplitude of the reflectedlight 54, which depends on the length of the combined light path 52, 54.

Referring now to FIGS. 7A-7B, additional embodiments of a pressuresensor with a micro-fluidic chamber 1 are illustrated wherein thedisplacement of the flexible membrane 120 is determined by measuring acapacitance. For example, referring to FIG. 7A, a first capacitorelectrode 61, for example a thin metal foil, may be arranged adjacent tothe flexible top cover membrane 120. Alternatively the membrane 120itself can comprise a capacitor electrode 61, for example by coating itwith a conducting material.

Still referring to FIGS. 7A-7B, insulating spacer elements 63 may definea distance between said first capacitor electrode 61 and a secondcapacitor electrode 62, located on top of the spacer elements 63 and thefirst capacitor electrode 61. The two capacitor electrodes 61, 62 may beelectrically isolated from each other, and thus act as a capacitor witha capacitance C, which can be measured. With increasing internalpressure in the micro-fluidic chamber 1, the flexible, resilientmembrane 120 may bulge outwards. The first capacitor electrode 61 maythen be displaced towards the second capacitor electrode 62. As aresult, the capacitance C increases, which can be detected and used todetermine the deformation of the membrane 12, 120, and the internalpressure in the chamber 1 causing said deformation, respectively.

As the internal pressure increases, the first capacitor electrode 61 mayeventually touch the second capacitor electrode 61, and the ohmicresistance R between the two layers drops to zero. This event may alsobe detected by suitable electronic means, and can be used—in addition oras an alternative to the capacitance—as an input for a control system ofan infusion pump device.

Referring now to FIG. 7B, in another embodiment, a capacitive detectionsystem 6 is illustrated wherein an additional insulating layer 64 isarranged between the spacer elements 63 and the second capacitorelectrode 62. Said additional layer 64 may inhibit a short-circuitbetween the two capacitor electrodes 61, 62, which can be preferable,depending on the used capacitance measurement circuitry.

In yet another embodiment, the second capacitor electrode 62 may belocated on the opposite side of the chamber 1, below the bottomstructure, or integrated into the bottom structure.

In another embodiment, micro-fluidic chambers may be utilized indegassing devices for fluidic systems, such as in infusion pump devicesfor liquid medicaments. For example, referring to FIG. 8, one exemplaryembodiment of a degassing device with a micro-fluidic chamber 1 isillustrated. The degassing device with a micro-fluidic chamber 1 maycomprise a rigid bottom structure 11 and a gas-permeable membrane 121 asthe top layer 12. In one embodiment, the gas permeable membrane 121 maycomprise a relatively high stiffness. Such an embodiment may be used,for example, in a fluidic system of an infusion pump device, where itcan be arranged in different positions along the liquid stream.

As discussed above, prior to the first use, the degassing device with amicro-fluidic chamber can be filled without air bubbles, independent onthe orientation of the device in space, due to the characteristics ofthe micro-fluidic chamber 1. Then, during the operational use of thefluidic system, an air bubble 71 may be flushed into the degassingdevice, along with the stream of liquid 4, and it can move along themeandering fluid channel 2. The interface tensions may inhibit theentrance of even of small air bubbles into the gap 3. However, the air 7in the air bubble 71 may nonetheless be able to pass the gas-permeablemembrane 121, provided that there is a sufficiently high difference ofthe partial pressure of the gas between the fluidic system and the otherside of the gas permeable membrane. For an air bubble in the fluidicsystem the partial gas pressure may be substantially similar to theliquid pressure.

When the surface characteristics of the walls 13, the bottom structure11, and the gas permeable membrane 121 are selected, it may becomeenergetically preferable for an air bubble 71 to be in contact with thegas permeable membrane 121. However, in another embodiment, it is alsopossible that an air bubble may be drained through the gas permeablemembrane indirectly, via the liquid, since the gas can be solved in theliquid. This effect may assist in the removal of small air bubbles witha large surface compared to their volume. Although the air bubbles 71may not enter the gap 3, gas 7 solved in the liquid may migrate into thegap 3, and permeate through the membrane 121. Thus a degassing devicewith a micro-fluidic chamber 1 may have a larger effective membranesurface compared to the operational internal volume, which may correlateto a faster dissolution of air bubbles and reduced dead volume.

In one embodiment, to provide the air bubbles more time to drain throughthe gas-permeable membrane, while at the same time maintaining asufficiently high through-put of liquid, a degassing device may becombined with a bubble trap.

Referring now to FIGS. 9A-9B, two additional exemplary embodiments ofdegassing devices are illustrated. Specifically, as illustrated in FIG.9A, two additional outlet openings 23 may be located at differentpositions along the meandering fluid channel 2, from which additionaloutlet conduits 231 branch off. Downstream of the main outlet 22 theoutlet conduits 221, 231 may converge again to a common outlet conduit.The additional outlet openings 23 may be smaller than the main outletopening 22. In one particular embodiments, the width of the narrowoutlets 23 may be 50% or less of the width of the fluid channel 2. Foran air bubble with certain dimensions, this may be energetically lessfavorable to enter the narrow outlet 23, due to the interface tensions,than to stay in the comparably wide fluid channel 2. There, the bubblesmay continue to drain through the gas-permeable membrane. Thus, thechamber 1 may act as a bubble trap. Since three outlets 23, 22 areavailable, the through-put of liquid through the degassing device may beincreased.

Referring now to FIG. 9B, another exemplary embodiment of a degassingdevice with a micro-fluidic chamber 1 is illustrated comprising anadditional conduit 241 bypassing the chamber 1. The bypass conduit 241may directly connect the inlet conduit 221 to the outlet conduit 221. Inone embodiment, the width of the inlet 24 of the bypass conduit 241 maybe much smaller, such as, 50% or less, than the width of the inletconduit 211. In such an embodiment, it may thereby be not favorable foran air bubble to enter the inlet 24 and bypass conduit 241, and the airbubble may enter the degassing device, where it can dissolve. Asillustrated in the embodiment seen if FIG. 9B, the outlet 22 of themicro-fluidic chamber 1 may be comprise a relatively narrowerembodiment. In such an embodiment, it may act as a bubble trap, keepingany air bubble in the degassing device. In one particular embodiment,the width of the outlet 22 may be 50% or less of the width of the fluidchannel 2. To ensure that both the bypass conduit 241 and themicro-fluidic chamber 1 are completely filled during the first fillingprocedure, a flow barrier or a similar means may additionally be used.

In one exemplary embodiment, the additional outlets 231 in FIG. 9A andthe bypass 241 in FIG. 9B may also useful in a pressure sensor, in orderto increase the overall capacity of the fluidic system.

It should now be appreciated that micro-fluidic chambers as disclosedherein may provide a smaller dead volume that may be fillable withoutair remaining in the chamber. Such micro-fluidic chambers may be filledessentially independent on its orientation in space such that it may beprovided as a pressure sensor for use in a fluidic system, particularlyin an infusion pump device for liquid medicaments. Degassing devices mayalso be provided comprising the micro-fluidic chambers for use in afluidic system, and particularly, in an infusion pump device for liquidmedicaments. Furthermore, infusion pump devices or parts of an infusionpump device, and liquid medicament delivery systems can comprise suchmicro-fluidic chambers, such as pressure sensor and/or a degassingdevice.

It is noted that the terms “substantially” and “about” may be utilizedherein to represent the inherent degree of uncertainty that may beattributed to any quantitative comparison, value, measurement, or otherrepresentation. These terms are also utilized herein to represent thedegree by which a quantitative representation may vary from a statedreference without resulting in a change in the basic function of thesubject matter at issue.

While particular embodiments have been illustrated and described herein,it should be understood that various other changes and modifications maybe made without departing from the spirit and scope of the claimedsubject matter. Moreover, although various aspects of the claimedsubject matter have been described herein, such aspects need not beutilized in combination. It is therefore intended that the appendedclaims cover all such changes and modifications that are within thescope of the claimed subject matter.

What is claimed:
 1. A micro-fluidic chamber for use in a liquidmedicament delivery system, the micro-fluidic chamber comprising: abottom substrate and a top cover, the top cover being spaced from thebottom substrate so as to define a height of the micro-fluidic chamber;wherein, two or more walls or fillings are positioned in themicro-fluidic chamber, the walls or fillings forming a fluid channelbetween the walls or fillings, the fluid channel extending from an inletconduit connected to an inlet of the micro-fluidic chamber to an outletconduit connected to an outlet of the micro-fluidic chamber; wherein,each of the walls or fillings has a height less than the height of themicro-fluidic chamber so as to define a fluid gap between a top surfaceof each wall or filling and the top cover; and wherein, the dimensionsof the walls or fillings and the micro-fluidic chamber are such that thefluid gap will be filled with liquid by capillary forces via the fluidchannel when liquid is introduced into the micro-fluidic chamber;wherein, the top cover comprises a flexible membrane.
 2. Themicro-fluidic chamber of claim 1, wherein the top cover comprises agas-permeable membrane.
 3. The micro-fluidic chamber of claim 1, whereinat least one of a part of the surface of the bottom structure, thewalls, and the top cover facing toward an inner volume of themicro-fluidic chamber is hydrophilic.
 4. The micro-fluidic chamber ofclaim 1, wherein a height of the fluid gap is from 0.02 to 0.2 mm. 5.The micro-fluidic chamber of claim 4, wherein a height of the fluid gapis from 0.05 and 0.15 mm.
 6. The micro-fluidic chamber of claim 1,wherein the fluid channel comprises a meander-like shape.
 7. Themicro-fluidic chamber of claim 1, wherein the fluid channel extendsuninterrupted from the inlet conduit to the outlet conduit.
 8. Apressure sensor for use in a liquid medicament delivery system, thepressure sensor comprising: a rigid bottom structure and a top cover,the top cover comprising a flexible, resilient membrane being spacedfrom the rigid bottom structure so as to define a height of a chamber;wherein, two or more walls or fillings are positioned in the chamber,the walls or fillings forming a fluid channel between the walls orfillings, the fluid channel extending from an inlet conduit connected toan inlet of the chamber to an outlet conduit connected to an outlet ofthe chamber; wherein, each of the walls or fillings has a height lessthan the height of the chamber so as to define a fluid gap between a topsurface of each wall or filling and the top cover; wherein, the topcover comprises a flexible membrane; wherein, the dimensions of thewalls or fillings and the chamber are such that the fluid gap will befilled with liquid by capillary forces via the fluid channel when liquidis introduced into the chamber; and wherein, when there is no pressuredifference between an external pressure of the chamber and an internalpressure of the chamber, the top cover remains flat and when theexternal pressure of the chamber is less than the internal pressure, thetop cover bulges outwards.
 9. The pressure sensor of claim 8, whereinthe top cover comprises a gas-permeable membrane.
 10. The pressuresensor of claim 8 wherein, a detection system is arranged to measure adeformation of the top cover of the chamber.
 11. The pressure sensor ofclaim 8 wherein, wherein at least one of a part of the surface of therigid bottom structure, the walls, and the top cover facing toward aninner volume of the chamber is hydrophilic.
 12. The pressure sensor ofclaim 8 wherein, wherein a height of the fluid gap is from 0.02 to 0.2mm.
 13. The pressure sensor of claim 12 wherein, wherein a height of thefluid gap is from 0.05 and 0.15 mm.
 14. The pressure sensor of claim 8,wherein the fluid channel comprises a meander-like shape.
 15. Thepressure sensor of claim 8, wherein the fluid channel extendsuninterrupted from the inlet conduit to the outlet conduit.